KR100926086B1 - Methods and System for QoS-Guaranteed Multi-Mode Fast Mobility Management in Wireless Networks - Google Patents

Abstract

The present invention provides a service quality guaranteed multi-mode high-speed mobility management method that can efficiently support IP-based real-time multimedia services regardless of the type of wireless network when a mobile terminal equipped with a plurality of wireless communication interfaces moves between cells in a wireless network. It is about the system.

The present invention allows data to be transmitted and received through an open mobility management server located between a mobile terminal and a counterpart terminal, and dynamically establishes a two-way tunnel with an open mobility management server through a plurality of wireless networks according to the quality of service while moving. It is a service quality guaranteed multi-mode high-speed mobility management method and system that can efficiently provide real-time IP-based multimedia service without time delay or packet loss due to handover.

The present invention is a high speed without knots independently of the transmission protocol or applications used by mobile terminal users such as wireless communication terminal, PDA, notebook, Internet phone or smart phone to move between various wireless networks such as WiFi, WiMAX, 3G, 4G Handover is possible and there is an effect that can be applied to IPv6 network as well as the existing IPv4 network.

Mobility management, high speed handover, service quality guaranteed mobility management

Description

Quality Assurance Multi-Mode Fast Mobility Management Method and System in Wireless Networks

1 is a block diagram of a service quality guaranteed high-speed mobility management system according to the present invention

Figure 2: Open mobility management server and mobile terminal structure according to the present invention

Figure 3: Detailed structure of mobility management information table according to the present invention

Figure 4: Call setup, parallel data transmission and call cancellation algorithm through the open mobility management server according to the present invention

5 is a parallel transmission mobility management algorithm of the open mobility management server according to the present invention

6 is a service quality guarantee mobility management algorithm of a mobile terminal according to the present invention.

According to the present invention, when a mobile terminal equipped with two or more wireless communication interfaces moves between homogeneous or heterogeneous wireless network cells, IP (Internet Protocol) -based voice calls, video calls, and video conferencing are performed in real time without degrading service quality. The present invention relates to a service quality guaranteed multi-mode high-speed mobility management method and system capable of efficiently supporting a real-time multimedia service. The wireless network may include a wireless fan (Pan), a personal area network (LAN), a wireless local area network (LAN), a metropolitan area network (MAN), and a wireless wide area network (WAN).

Looking at the conventional technology related to the present invention, the next-generation wireless communication network is a wireless fan, wireless LAN and wireless man, which are being developed in the IEEE 802 working group, together with broadband wireless completion such as 3G and 4G, interconnected on the basis of All-IP. Will be constructed. In these various wireless communication networks, the mobile terminal operates in a multi-mode equipped with a plurality of different wireless communication interfaces to support IP-based mobile real-time multimedia services such as mobile VoIP, mobile IPTV, and mobile real-time video conferencing. From the user's point of view, although these next-generation wireless networks have high-speed packet transmission capability, they provide a high-speed mobility management function that guarantees the quality of service required to provide the real-time multimedia service when a mobile terminal moves between homogeneous or heterogeneous wireless networks. There is a problem that can not be.

Looking at the prior art of mobility management when a mobile terminal moves between various wireless cell cells, the mobility management of a dual-mode phone that can switch between the GSM (Global System for Mobile Communications) network and IEEE 802.11 wireless LAN without service interruption There is a GAN (Generic Access Network) structure suggested by the ETSI TS standard in the UMA forum. In addition, IMS (Internet Multimedia System) Forum is researching seamless VoIP support in various wired / wireless converged communication networks based on Session Initiation Protocol (SIP). Meanwhile, FMCA (Fixed Mobile Convergence Alliance) has announced the linkage technology between Bluetooth wireless fan and cellular wireless network. However, GAN or IMS technology is a technology for providing a seamless IP connection from the service provider's point of view, and there is a problem of service interruption when the IP of the mobile terminal is changed, and it provides a service quality guarantee or a high speed handover function while moving. can not do.

In addition, there are MIP (Mobile IP), Fast MIP, Hierarchical MIP developed by IETF, Internet standardization organization for IP mobility management, SCTP-ADDIP for mobility management in transport layer, and SIP for mobility management in application layer. However, most of these IETF handover international standards do not provide high-speed mobility management to guarantee service quality between various heterogeneous wireless networks. Recently, in the IETF Multi-Homing working group, when a mobile node has a plurality of temporary IP addresses by mounting a plurality of different interfaces, a method for improving distributed system service reliability or performance related to the mobile node is studied. have. Unlike the research in IETF multihoming, however, in the present invention, multi-homing walking is performed by establishing parallel distributed packet tunnel through SIP-based open mobility management server located in the middle rather than end-to-end using multiple interfaces. This is different from the group's current research.

Other related researches have developed MIH (Media Independent Handover) standard interface to enable interworking of various wireless networks in data link layer in IEEE 802.21 Working Group, but it does not suggest the method of guaranteeing the quality of service when the terminal moves. In conclusion, despite the fact that many technologies and international standards have been developed to date, service quality guaranteed high-speed wireless network mobility management, which guarantees seamless mobility to users when mobile terminals move between various wireless networks, is not properly provided. It is true.

The technical problem to be achieved by the present invention is to solve the problems of the prior art as described above, a variety of mobile terminals such as mobile phones, Internet phones, smart phones, laptops in a wireless network between the same or different types of wireless network cells Its purpose is to provide a service quality guaranteed high-speed mobility management function that can efficiently support IP-based multi-party real-time multimedia services regardless of the type of wireless network.

Another object of the present invention is to increase the degraded quality of service by transmitting data in parallel by dynamically forming a two-way tunnel through a plurality of new wireless networks when the quality of service is degraded while the mobile station is in motion. Independent of the above, and to provide a service quality guaranteed high-speed mobility management structure and function without packet loss or time delay due to handover.

Another object of the present invention is to provide a service quality guaranteed high-speed mobility management structure and function applicable to both IPv4 and IPv6 networks.

The present invention provides a service quality guaranteed multi-mode high-speed mobility management method that can efficiently support IP-based real-time multimedia services regardless of the type of wireless network when a mobile terminal equipped with a plurality of wireless communication interfaces moves between cells in a wireless network. It is about the system.
A first aspect of the present invention for achieving the above object is, IP-based real-time regardless of the type of wireless network when a mobile terminal having a multi-mode communication interface having a plurality of wireless communication interfaces in a wireless network moves between cells The present invention relates to a service quality guaranteed multi-mode fast mobility management method in an open mobility management server that efficiently supports a multimedia service.
(a) When a call setup request is made from a mobile terminal to a specified counterpart, the mobility management information table includes the user ID provided from the mobile terminal, the user's unique IP address, the temporary IP address currently being used, and the location of the current mobile terminal. Registering and storing in; (b) completing a call setup between the mobile terminal and the counterpart terminal; (c) After completing the call setup between the mobile terminal and the counterpart terminal, a tunnel between the open mobility management server and the mobile terminal is established by using the unique IP address of the open mobility management server and the temporary IP address of the mobile terminal. Transmitting; (d) When a new temporary IP address and wireless network information of a newly activated wireless communication interface are provided from the mobile terminal, open mobility management using a unique IP address of the open mobility management server and a new temporary IP address of the mobile terminal. Forming a new tunnel between the server and the mobile terminal and transmitting and receiving data packets in parallel through the existing tunnel and the new tunnel; And (e) if a removal request for one of the currently activated tunnels is generated from the mobile terminal, removing the corresponding tunnel.
(B) step (b1) of registering the IP address of the opposite terminal in the mobility management information table; And (b2) transmitting a call setup and response signal to the temporary IP address of the mobile terminal and the IP address of the counterpart terminal. The call setup is preferably completed between the counterpart terminal and the mobile terminal.
In step (d) of the method of guaranteeing a quality of service type multi-mode fast mobility management according to the first aspect, the wireless network information of a new temporary IP address and a newly activated wireless communication interface is provided from the mobile terminal. It is preferable to grasp the congestion status information or access authority for and send it to the mobile terminal.
The mobility management information table of the service quality guaranteed multi-mode high-speed mobility management method according to the first feature described above includes user identification information, unique IP address, number of IP connections connected to the mobile terminal in parallel, It includes current connection information and service quality information, the current connection information preferably includes a temporary IP address, authentication information, bandwidth information.
According to a second aspect of the present invention, a service quality guaranteed multi-mode fast mobility management system includes a mobile terminal having a multi-mode communication interface including a plurality of wireless communication interfaces; And an open mobility management server that supports an IP-based real-time multimedia service regardless of the type of a wireless network when the mobile terminal moves between cells.
The mobile terminal comprises: call setup completion means for providing mobility management information to the open mobility management server and requesting call setup with a specific counterpart terminal; After completion of call setup, if the tunnel is established by interworking with the open mobility management server, or the service quality of the existing tunnel is degraded, the dormant wireless communication interface is activated to connect to a new wireless network and receive a new temporary IP address to receive the open mobility. Mobility management unit to provide a management server to build a new tunnel; A parallel data transceiver for transmitting and receiving data in parallel through a plurality of tunnels established by the mobility manager; And a service quality monitor for monitoring a communication service quality of a tunnel between a mobile terminal and the open mobility management server and transmitting the monitoring information to the open mobility management server.
The open mobility management server may include: a mobility management information table configured to register and store mobility management information for a mobile terminal provided from a mobile terminal that is requested to establish a call with a specific counterpart terminal; Call setup completion means for completing call setup for the mobile terminal and the counterpart terminal according to the call setup request; After completing the call setup between the mobile terminal and the counterpart terminal, if a tunnel for data transmission between the open mobility management server and the mobile terminal is established, or a new temporary IP address and wireless network information of the newly activated wireless communication interface are provided from the mobile terminal, A mobility management unit for establishing a new tunnel between the mobile terminal and the open mobility management server, or removing the tunnel when a removal request for one of the currently activated tunnels is generated from the mobile terminal; A parallel data transceiver for transmitting and receiving data in parallel with the mobile terminal through the constructed plurality of tunnels; A service quality manager managing service quality for each tunnel formed for the mobile terminal; It is provided.
In the service quality guaranteed multi-mode high-speed mobility management system according to the aforementioned second feature, the mobility management information includes a user ID, a user's unique IP address, a temporary IP address currently in use, and location information of a current mobile terminal. desirable.
In the service quality guaranteed multi-mode high-speed mobility management system according to the above-described second feature, if the mobility management unit of the open mobility management server is provided with wireless network information of a newly activated wireless communication interface from the mobile terminal, It is desirable to grasp the congestion status information or access authority and transmit it to the mobile terminal.
In the service quality guaranteed multi-mode high-speed mobility management system according to the above-described second feature, the parallel data transceiver of the mobile terminal and the parallel data transceiver of the open mobility management server are provided with a plurality of tunnels formed between the open mobility management server and the mobile terminal. It is preferable to have a parallel packet distributor for transmitting packets in parallel via a parallel packet collector, and a parallel packet collector for collecting packets arriving through the plurality of tunnels.
In the service quality guaranteed multi-mode high-speed mobility management system according to the aforementioned second feature, the mobility management information table of the open mobility management server is parallel to the user identification information, unique IP address, and the mobile terminal for the currently set mobile terminal. It includes the number of IP connection, the current connection information and the service quality information connected to the current connection information, it is preferable that the current connection information includes a temporary IP address, authentication information, bandwidth information.
According to a third aspect of the present invention, a mobile terminal includes a multi-mode communication interface including a plurality of wireless communication interfaces; Call setup completion means for providing mobility management information to an external open mobility management server and requesting call setup with a specific counterpart terminal; After the call setup is completed, if the tunnel is established with the open mobility management server or the service quality of the existing tunnel is degraded, the dormant wireless communication interface is activated to access a new wireless network and receive a new temporary IP address to receive the open mobility management. A mobility management unit providing a server to build a new tunnel; A parallel data transceiver for transmitting and receiving data in parallel with the open mobility management server through the constructed plurality of tunnels; A service quality monitor that monitors the communication service quality of the tunnel with the open mobility management server and transmits the monitoring information to the open mobility management server; when moving between cells in association with an external open mobility management server, Regardless of the type, IP-based real-time multimedia service can be provided.
An open mobility management server according to a fourth aspect of the present invention includes a multi-mode communication interface including a plurality of wireless communication interfaces, a user ID for a mobile terminal requesting to establish a call with a specific counterpart terminal, and a unique IP address of the user. A mobility management information table for registering and storing a temporary IP address currently being used and a current location of the mobile terminal; Call setup completion means for completing call setup for the mobile terminal and the counterpart terminal; After completing the call setup between the mobile terminal and the counterpart terminal, if a tunnel for data transmission between the open mobility management server and the mobile terminal is established, or a new temporary IP address and wireless network information of the newly activated wireless communication interface are provided from the mobile terminal, A mobility management unit for establishing a new tunnel between the mobile terminal and the open mobility management server or removing the corresponding tunnel when a removal request for one of the currently activated tunnels is generated from the mobile terminal; Parallel data transmission and reception unit for transmitting and receiving data in parallel through the established plurality of tunnels; when the mobile terminal moves between cells in a wireless network efficiently supports IP-based real-time multimedia services regardless of the type of wireless network do.

Hereinafter, the configuration and operation of the embodiments of the present invention with reference to the accompanying drawings, the configuration and operation of the present invention shown and described in the drawings will be described by at least one embodiment, whereby the present invention described above The technical idea and its core composition and operation are not limited.

With reference to the drawings shown so that the present invention can be easily understood. Figure 1 shows the configuration of a service quality guaranteed high-speed mobility management system. 2 is an open mobility management server and a mobile terminal structure. 3 shows a detailed structure of the mobility management information table. 4 is a call setup, parallel data transmission and call termination algorithm through an open mobility management server. 5 is a parallel transmission mobility management algorithm of an open mobility management server. 6 is a service quality guarantee mobility management algorithm of a mobile terminal.

1 is a block diagram illustrating a service quality guaranteed multi-mode fast mobility management system for guaranteeing service quality in various wireless networks according to the present invention. The communication quality of service referred to in the present invention is a data rate (or bandwidth) to be guaranteed even when the quality of service is changed due to a decrease in signal strength or congestion of a wireless network during the movement of a mobile station for a specific multimedia communication service. It can be defined as loss and time delay and response time.

The overall scenario of the service quality guaranteed multi-mode fast mobility management system according to the present invention shown in FIG. 1 is as follows. First, the mobile terminal B communicates with the other terminal A through an Open Mobility Management Server (OMS) via a wireless LAN base station and router 1. In this case, an open mobility management server and a router may operate as one integrated system. B moves away from the base station on the move and degrades the quality of service due to a decrease in received radio wave strength. In order to compensate for the deteriorated quality of service, the mobile station B activates the wireless network interface and accesses the wireless network to receive a temporary IP from the router 2 to establish an open mobility management server and a tunnel 2. And the existing tunnel 1 and the newly set tunnel 2 is used to send and receive data in parallel at the same time. This increases the available effective bandwidth to compensate for the bandwidth reduction in tunnel 1 to ensure quality of service. The mobile station B is disconnected from the WLAN access point as it continuously moves, connects to the wireless man, connects to the open mobility management server through the tunnel 3, and communicates with the mobile station A. In this case, after connecting to tunnel 3, if the quality of service is guaranteed, tunnel 2 is removed.

By doing so, the mobile terminal B communicates with the open mobility management server directly at the terminal by forming an end-to-end tunnel with the terminal, unlike the conventional handover method in the conventional mobile communication network. . Unlike conventional handover methods, packet loss or delay due to handover can be eliminated while moving by transmitting and receiving data in advance by connecting to a new wireless network that can be accessed when service quality is deteriorated. Unlike the existing international IP handover standard based on IETF Mobile IP, mobile terminals A and B use SIP-based user ID to set up call through open mobility management server. Mobility and service mobility can also be provided. In particular, if the terminal A has a tunneling function like the mobile terminal B, the user ID of B may be registered in the open mobility management server to establish a tunnel between both ends, and may directly transmit and receive data. In this case, seamless fast handover is supported not only for B but also for A while moving. 1 tunnel 4 illustrates this case. Finally, the mobile station B may communicate with the mobile station C connected to the router 1 without using a tunnel.
Hereinafter, the configuration and operation of a mobile terminal and an open mobility management server of a service quality guaranteed multi-mode fast mobility management system according to the present invention will be described in detail with reference to FIGS. 1 to 6.

FIG. 2 shows the structure of an open mobility management server and a mobile terminal system for the service quality guaranteed high-speed mobility management shown in FIG. 1. Here, the term open means that the open mobility management server provides a SIP-based mobility management interface for mobility management. First, FIG. 2A is a structural diagram schematically illustrating only a structure for mobility management of a mobile terminal B. As shown in FIG. As shown in (a) of FIG. 2, the mobile terminal B includes a multi-mode communication interface, a call setup completion unit, a mobility management unit, a parallel data transmission and reception unit, a quality of service monitor, and a power manager. It consists of L2 mobility manager and L3 mobility manager, and the parallel data transmitter / receiver consists of a parallel packet distributor and a parallel packet collector. The multi-mode communication interface may be composed of a plurality of wireless communication interfaces, such as a wireless fan, a wireless LAN, a wireless man, a wireless arm, and the like, and may wirelessly communicate with a server through one or more of them.
The call setup completion unit provides mobility management information to an external open mobility management server, requests a call setup with a specific counterpart terminal, and sets a call when receiving a response message from the counterpart terminal through the open mobility management server. Will complete. The mobility management information provided by the call setting completion unit to an external open mobility management server includes a user ID for the mobile terminal, a unique IP address of the user, a temporary IP address currently being used, and current location information of the mobile terminal. .
The mobility manager comprises a multimode L2 mobility manager and an L3 mobility manager. The multi-mode L2 mobility manager interworks with the open mobility management server to search for a wireless network link that can be connected when moving and performs two-layer handover, and the L3 mobility manager interoperates with the open mobility management server to ensure a quality of service. Layer 3 handover is performed.
The parallel data transceiver includes a parallel packet divider and a parallel packet combiner, wherein the parallel packet divider transmits packets in parallel through a plurality of tunnels formed between an open mobility management server and a mobile terminal, and the parallel packet combiner passes through a plurality of tunnels. Collect packets that arrive.
The mobility management unit and the parallel data transmission / reception unit interoperate with each other and operate according to the service quality guarantee mobility management algorithm shown in FIG. 6. A detailed description of the service quality guaranteed mobility management algorithm shown in FIG. 6 will be given later.
The service quality monitor monitors the communication service quality of the tunnel with the open mobility management server and transmits the monitoring information to the open mobility management server. The power manager requests the removal of the tunnel from the open mobility management server when the radio wave strength of a specific wireless network in which a tunnel is formed is reduced to a predetermined value or when data transmission and reception is completed or the connection between the mobile terminal and the opposite terminal is terminated. Keep the wireless communication interface dormant.
The mobile terminal having the above-described configuration is provided with a multi-mode communication interface composed of a plurality of wireless communication interfaces, and is an IP-based real-time multimedia service regardless of the type of wireless network when moving between cells in conjunction with an external open mobility management server. Can be provided.
The mobile terminal is equipped with a multi-mode communication interface composed of a plurality of wireless communication interfaces, which can be configured as a wireless fan, a wireless LAN, a wireless man, a wireless light, and communicate with an open mobility management server. The multimode communication interface may be composed of two or more identical wireless network communication interfaces in the case of a homogeneous wireless network. In (a) of FIG. 2, the parallel packet distributor plays a role of transmitting packets in parallel through an open mobility management server and a plurality of data transmission tunnels, and the parallel packet collector collects packets arriving through a plurality of data transmission tunnels. To send to the other side. The power manager plays a role of minimizing power consumption that may occur when communicating through a plurality of wireless communication modules in the case of a mobile terminal having a multi-mode communication interface. The multi-mode L2 mobility manager searches for a wireless network link that can be connected when the mobile station moves and performs a layer 2 handover function. In addition, it communicates with the Media Independent Handover (MIH) server in the mobile communication system through the IEEE 802.21 MIH to import and send information required for layer 2 (L2) mobility management. The L3 mobility manager communicates with an open mobility management server to perform three-layer fast handover function to guarantee the quality of service. The service quality monitor monitors the quality of a specific service currently provided by using packet monitoring technology and notifies the open mobility management server.
Hereinafter, the configuration of the open mobility management server of the system according to the present invention. As shown in (b) of FIG. 2, the open mobility management server includes a mobility management information table, a service quality manager, a security manager, a call setup completion unit, a mobility manager, a parallel data transmitter and receiver, and a service quality monitor. The mobility management unit includes an L3 mobility manager, and the parallel data transmission and reception unit includes a parallel packet distributor and a parallel packet collector.
The mobility management information table includes mobility management-related IETF SIP-based user information, a currently connected IP address, and mobility management policy to be applied when selecting a plurality of wireless networks. Register and store the user ID, the unique IP address of the user, the temporary IP address currently in use, and the current location of the mobile terminal. The mobility management information table may include a user ID, a unique IP address, a number of IP connections connected in parallel to the mobile terminal, a current connection information, and a service quality information. The current connection information may include: Contains temporary IP address, authentication information, and bandwidth information.
The call setup completion means registers the IP address of the counterpart in the mobility management information table according to the call setup request from the mobile terminal, and then transfers the call setup and response message to the temporary IP address of the mobile terminal and the IP address of the counterpart terminal. Complete call setup between both terminals.
The mobility management unit, including the L3 mobility manager, detects a congestion state or access authority for the wireless network and transmits it to the mobile terminal when the wireless network information of the newly activated wireless communication interface is provided from the mobile terminal.
The parallel data transceiver includes a parallel packet distributor and a parallel packet collector. The parallel packet distributor transmits packets in parallel through a plurality of tunnels formed between the open mobility management server and the mobile terminal, and the parallel packet collector collects the packets arriving through the plurality of tunnels and sends them to the counterpart terminal.
The mobility management unit and the parallel data transmission / reception unit interwork with each other according to the parallel transmission mobility management algorithm shown in FIG. 5 to transmit and receive packets in parallel using a plurality of tunnels with the mobile terminal.
The service quality manager manages the service quality of each tunnel formed for the mobile terminal, and in particular, manages the service quality such as packet loss, delay time, response time, etc. between the mobile terminal and the open mobility management server. The security manager is in charge of authentication, control, data encryption, etc. to the wireless network or open mobility management server.The event manager handles events when they occur in other networks, and the automatic configuration manager helps automatic wireless network selection and configuration. . The roles of the Quality of Service Monitor, L3 Mobility Manager, Parallel Packet Splitter, and Parallel Packet Collector are similar to those of mobile terminals.
The open mobility management server having the above-described configuration efficiently supports real-time multimedia services based on IP regardless of the type of wireless network when the mobile terminal moves between cells in the wireless network.

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3 is a detailed structure of the mobility management information table. In FIG. 3, the user ID may be represented by an email address or a phone number defined in the SIP standard, and the unique IP address represents a home internet address assigned to the user ID. The parallel connection number indicates the number of IP connections connected in parallel to the mobile terminal of the current user ID. The current connection information represents the current connection information of the mobile terminal and has n triple information (temporary IP address, authentication, bandwidth) when the mobile terminal uses n IP connections. The effective bandwidth of the quality of service is defined as the bandwidth sum of the n connections. Others include current location information of the mobile terminal and authentication of wireless networks accessible from the location. The unique IP address can use IPv6 as well as IPv4. Because both terminals provide tunneling function, IPv6 application can be supported because data can be exchanged with each other through end-to-end tunnel with unique IP address as IPv6. Therefore, the structure for mobility management of the open mobility management server proposed in the present invention can be used by using a combination of IPv4 or IPv6 when using the same type of unique IP address between both ends and using the same type of temporary IP address between both ends.

4 is a call establishment algorithm between the user and the parallel data transmission call through the Open Mobility Management Server (OMS). In FIG. 4, the open mobility management server plays a role of a gateway for relaying call setting signals between both ends when setting up a call. In the case of a signal using SIP, since the terminal can process the SIP signal, the role of the open mobility management server is relatively simple. That is, the same role as the conventional SIP gateway except for establishing a tunnel between the open mobility management server and the user when transmitting data. When the opposite terminal and the mobile terminal are connected to the same router, it is not necessary to establish and use a tunnel for data transmission as described in FIG.
Referring to FIG. 4, when a call setup request is requested from the user terminal A to the user terminal B, the open mobility management server checks the current access position and the temporary IP address of the user terminal B. Next, it is determined whether the user terminal B is currently connected to the external network.
In the determination process, if the user terminal B is currently connected to the external network, the user ID and IP address of the user terminal A is registered in the mobility management information table of the open mobility management server and the call is set to the temporary IP address of the user terminal B. Relay by sending signal message. Next, if the call setup is not completed, the call setup signal message is relayed to the temporary IP address of the user terminal B. After the call setup is completed, a temporary IP address is established between the user terminal B and the open mobility management server to establish a tunnel for new parallel data transmission and perform parallel transport mobility management. Next, the open mobility management server delivers the data received from the user terminal B through the tunnel to the user terminal A and the data received from the user terminal A to the user terminal B through the tunnel.
In the determination process, if the user terminal B is not currently connected to the external network, the call setup signaling message is transmitted to the unique IP address of the user terminal B and relayed. Next, if the call setup is not completed, the call setup signaling message is relayed to the unique IP address of the user terminal B and relayed. When the call setup is completed, the user terminal A transmits and receives multimedia data using the unique IP address of the user terminal B.
When the communication between A and B is completed, the open mobility management server relays the call termination signal, removes the user terminal A information from the mobility information management table, and removes the tunnel with the user terminal B.

5 illustrates in more detail the parallel transport mobility management algorithm of the open mobility management server of FIG. The algorithm of FIG. 5 is performed after call setup in FIG. 4 is completed. In FIG. 4, the location information or the degree of congestion of the User_ID can be obtained by requesting network management information of each corresponding wireless network by referring to nearby accessible wireless network information sent by the User_ID. The access rights or authentication information for the wireless network may be owned by an open mobility management server or may be directly owned by a mobile terminal user. Once the mobile terminal accesses the wireless network, the open mobility management server grasps the service quality and bandwidth information through the wireless network, stores it in the current connection information of the mobility management information table, and continues to modify and supplement it.
Referring to FIG. 5, when information about a wireless network accessible from a mobile terminal is requested, the open mobility management server determines a congestion level of a nearby wireless network currently accessible by referring to location information of the mobile terminal, The IPSec secure tunnel is established by referring to the temporary IP address, and the wireless network congestion information and authentication information are transmitted to the mobile terminal through the secure tunnel, and then terminated. When the new mobility management server is requested to establish a new tunnel from the mobile terminal, the open mobility management server establishes a bidirectional data tunnel between the temporary IP address of the mobile terminal and the fixed IP address of the open mobility management server and newly sets the bidirectional data tunnel in the mobility management information table. After registering, the mobile terminal notifies the completion of tunnel setup and terminates. When the open mobility management server is requested to remove a new tunnel from the mobile terminal, the corresponding tunnel is removed from the parallel transmission path established between the mobile terminal and the open mobility management server, and the registration information of the tunnel is deleted from the mobility management information table. It terminates after notifying completion of tunnel removal to mobile terminal.

6 shows a service quality guarantee mobility management algorithm of a mobile terminal. In FIG. 6, it is assumed that an initial connection is made with a specific wireless network. The mobile station first checks whether the effective bandwidth of the current transmission path satisfies the required bandwidth and, if not satisfied, activates the dormant multimode communication interfaces using the radio link detector. If there is a new wireless network that can be connected, the mobile terminal sends network information to the open mobility management server through the existing wireless connection to bring the authentication method required for the connection.

If it is difficult to obtain access authority information for a new wireless network from an open mobility management server, the L2 mobility manager obtains access information if the MIH server can be accessed locally. The L3 mobility manager then accesses the new wireless network and gets a temporary IP address for temporary use. Then, the temporary IP address is used to establish a tunnel with an open mobility management server to establish a new IP transmission path, establish a parallel packet transmission path in connection with an existing transmission path, and then transmit packets in parallel. This increases the effective transmission bandwidth. If the service quality is not satisfied when the data packet is exchanged in parallel by forming a new tunnel with the open mobility management server, the open mobility until the service quality of the mobile terminal is ensured through a plurality of different wireless networks that can be connected while moving. Dynamically establishes multiple parallel data transmission tunnels with the management server to transmit data. Lastly, if the radio wave strength is weakened by the distance from a specific wireless network, the connection with the wireless network is disconnected and the open mobility management server is notified to remove the corresponding tunnel. The above described processes are repeated until the effective bandwidth is satisfied. If the effective bandwidth is satisfied, the unnecessary power consumption is reduced by putting the unused wireless communication interface through the mobile manager's power manager.

When establishing a new tunnel to guarantee the quality of service, the second layer handover is completed using the handover information from the second layer using MIH-based or proprietary technology according to the mobile terminal's movement to secure a new temporary IP address in advance. Prepare for a handover by accessing a DHCP server or by using an autoconfiguration function to obtain a new temporary IP address in advance.After the two-layer handover is completed, the temporary IP address is immediately notified to the open mobility management server for handover. Knotless mobility management without packet loss or delay.

In summary, in the various wireless networks proposed by the present invention, the method and system of high quality mobility management system guaranteeing a new transmission path dynamically before the connection from a specific wireless network is disconnected using tunneling based parallel transmission technique. Since data is transmitted / received, the same or heterogeneous wireless network moves in the overlapped region, unlike the various handover methods. Thus, there is no delay due to packet loss or handover. Moreover, quality of service can be guaranteed because the required bandwidth can be obtained through a plurality of accessible wireless networks. In particular, unlike most existing handover methods, handover preparation is started based on the quality of service, which reduces the handover time required for acquiring temporary IP by starting the handover well before disconnection due to the decrease in radio wave strength. Can be.

The present invention is a mobile phone, Internet phone, PMP in a wireless network. UltraPC. When various mobile terminals such as smart phones and laptops move between the same or heterogeneous wireless network cells, regardless of the type of wireless network, it guarantees the service quality of IP-based real-time mobile multimedia service and gives high-speed mobility management function. By having a high industrial applicability is very high.

The present invention is a mobile phone, Internet phone, PMP in a wireless network. UltraPC. When various mobile terminals such as smart phones and laptops move between homogeneous or heterogeneous cells, regardless of the type of wireless network, it guarantees the service quality of IP-based real-time multimedia service and provides high-speed mobility management function.

Another effect of the present invention is to dynamically establish a two-way tunnel by accessing a number of new wireless networks when the quality of the wireless network communication service is degraded due to a decrease in received radio signals or a congestion of the network. Therefore, the service quality is improved by transmitting data in parallel, thereby improving quality of service, independent of upper transmission and application layers, and providing a service quality guaranteed fast mobility management function without packet loss or time delay due to handover.

Another effect of the present invention is that the mobile terminal is located in an open mobility management server or when both terminals have a tunneling function, there is an effect of providing the end-to-end mobility management function.

Yet another object of the present invention is to provide a service quality guaranteed fast mobility management function applicable to both IPv4 and IPv6 networks.

Claims (14)

Quality of service in an open mobility management server that efficiently supports IP-based real-time multimedia services regardless of the type of wireless network when a mobile terminal having a multi-mode communication interface having a plurality of wireless communication interfaces moves between cells in a wireless network In the guaranteed multi-mode fast mobility management method, (a) When a call setup request is made from a mobile terminal to a specified counterpart, the mobility management information table includes the user ID provided from the mobile terminal, the user's unique IP address, the temporary IP address currently being used, and the location of the current mobile terminal. Registering and storing in; (b) completing a call setup between the mobile terminal and the counterpart terminal; (c) After completing the call setup between the mobile terminal and the counterpart terminal, a tunnel between the open mobility management server and the mobile terminal is established by using the unique IP address of the open mobility management server and the temporary IP address of the mobile terminal. Transmitting; (d) When a new temporary IP address and wireless network information of a newly activated wireless communication interface are provided from the mobile terminal, open mobility management using a unique IP address of the open mobility management server and a new temporary IP address of the mobile terminal. Forming a new tunnel between the server and the mobile terminal and transmitting and receiving data packets in parallel through the existing tunnel and the new tunnel; And (e) if a removal request for one of the currently activated tunnels is generated from the mobile terminal, removing the tunnel; Quality assurance type multi-mode fast mobility management method comprising a. The method of claim 1, wherein step (b) (b1) registering an IP address of the opposite terminal in the mobility management information table; And (b2) transmitting a call setup and response signal to the temporary IP address of the mobile terminal and the IP address of the counterpart terminal; and providing a call quality between the counterpart terminal and the mobile terminal. High speed mobility management method. The method of claim 1, wherein in step (d), when the new temporary IP address and wireless network information of the newly activated wireless communication interface are provided from the mobile terminal, the congestion status information or access authority for the corresponding wireless network is determined. Quality assurance type multi-mode high-speed mobility management method characterized in that it is sent to the mobile terminal. The mobile terminal of claim 1, wherein the mobility management information table includes user identification information, a unique IP address, a number of IP connections connected in parallel to the mobile terminal, current connection information, and service quality information. The current connection information quality assurance type multi-mode fast mobility management method comprising a temporary IP address, authentication information, bandwidth information. The method of claim 1, wherein the step (d) of transmitting and receiving data packets in parallel through the existing tunnel and the new tunnel comprises: a plurality of open mobility management servers and mobile terminals until the quality of service of the mobile terminal is guaranteed. Quality of service guaranteed multi-mode fast mobility management method characterized in that the data transmission in parallel through the tunnel. 6. The method of claim 5, wherein the quality of service of the mobile station is determined by one or more of data rate, bandwidth, packet loss rate, delay time, and response time. A mobile terminal having a multimode communication interface including a plurality of wireless communication interfaces; And And an open mobility management server that supports an IP-based real-time multimedia service regardless of the type of wireless network when the mobile terminal moves between cells. The mobile terminal, Call setup completion means for completing a call setup by requesting a call setup with a counterpart terminal or receiving a response message through the open mobility management server; After completion of call setup, if the tunnel is established by interworking with the open mobility management server, or the service quality of the existing tunnel is degraded, the dormant wireless communication interface is activated to connect to a new wireless network and receive a new temporary IP address to receive the open mobility. Mobility management unit to provide a management server to build a new tunnel; A parallel data transceiver for transmitting and receiving data in parallel through a plurality of tunnels established by the mobility manager; And a service quality monitor for monitoring a communication service quality of a tunnel between a mobile terminal and the open mobility management server and transmitting the monitoring information to the open mobility management server. The open mobility management server, A mobility management information table for registering and storing mobility management information for a mobile terminal provided from a mobile terminal requested to establish a call with a specific counterpart terminal; Call setup completion means for completing call setup for the mobile terminal and the counterpart terminal according to the call setup request; After completing the call setup between the mobile terminal and the counterpart terminal, if a tunnel for data transmission between the open mobility management server and the mobile terminal is established, or a new temporary IP address and wireless network information of the newly activated wireless communication interface are provided from the mobile terminal, A mobility management unit for establishing a new tunnel between the mobile terminal and the open mobility management server, or removing the tunnel when a removal request for one of the currently activated tunnels is generated from the mobile terminal; A parallel data transceiver for transmitting and receiving data in parallel with the mobile terminal through the constructed plurality of tunnels; Quality assurance type multi-mode high-speed mobility management system characterized in that it comprises a. The system of claim 7, wherein the mobility management information includes a user ID, a unique IP address of the user, a temporary IP address currently being used, and location information of a current mobile terminal. 8. The method of claim 7, wherein the mobility management unit of the open mobility management server, when the wireless network information of the newly activated wireless communication interface is provided from the mobile terminal, grasps the congestion state information or access authority for the wireless network and transmits it to the mobile terminal. Quality assurance type multi-mode fast mobility management system, characterized in that the. 8. The method of claim 7, wherein the open mobility management server further comprises a service quality manager for managing the service quality for each tunnel formed for the mobile terminal, the service quality manager is a packet loss between the mobile terminal and the open mobility management server Quality assurance type multi-mode fast mobility management system, characterized in that for managing one or more of the delay time, response time. 8. The parallel packet splitter of claim 7, wherein the parallel data transceiver of the mobile terminal and the parallel data transceiver of the open mobility management server transmit packets in parallel through a plurality of tunnels formed between the open mobility management server and the mobile terminal. And a parallel packet collector for collecting packets arriving through the plurality of tunnels. 8. The mobility management information table of the open mobility management server includes: user identification information, unique IP address, number of IP connections connected in parallel to the mobile terminal, current connection information, and quality of service. And information, wherein the current connection information includes a temporary IP address, authentication information, and bandwidth information. delete delete

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